Microlithographic projection exposure apparatus

ABSTRACT

A microlithographic projection exposure apparatus contains an illumination system ( 12 ) for generating projection light ( 13 ) and a projection lens ( 20; 220; 320; 420; 520; 620; 720; 820; 920; 1020; 1120 ) with which a reticle ( 24 ) that is capable of being arranged in an object plane ( 22 ) of the projection lens can be imaged onto a light-sensitive layer ( 26 ) that is capable of being arranged in an image plane ( 28 ) of the projection lens. The projection lens is designed for immersion mode, in which a final lens element (L 5;  L 205;  L 605;  L 705;  L 805;  L 905;  L 1005;  L 1105 ) of the projection lens on the image side is immersed in an immersion liquid ( 34; 334   a;    434   a;    534 a). A terminating element ( 44; 244; 444; 544; 644; 744; 844; 944; 1044; 1144 ) that is transparent in respect of the projection light ( 13 ) is fastened between the final lens element on the image side and the light-sensitive layer.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of International Application PCT/EP04/005816, with an international filing date of May 28, 2004, The full disclosure of this International Application is incorporated herein by reference.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to microlithographic projection exposure apparatuses such as are used for the production of microstructured components. The invention relates, in particular, to projection exposure apparatuses with a immersion projection lens.

2. Description of Related Art

Integrated electric circuits and other microstructured components are conventionally produced by several structured layers being applied onto a suitable substrate, which may be, for example, a silicon wafer. In order to structure the layers, the latter are firstly covered with a photoresist that is sensitive to light of a particular wavelength range, for example light in the deep ultraviolet spectral region (DUV). Subsequently the wafer that has been coated in this way is exposed in a projection exposure apparatus. In this process, a pattern of diffracting structures contained in a mask is imaged onto the photoresist with the aid of a projection lens. Since the lateral magnification in this case is generally less than 1, projection lenses of such a type are frequently also referred to as reduction lenses.

After the photoresist has been developed, the wafer is subjected to an etching process, as a result of which the layer is structured in accordance with the pattern on the mask. The photoresist left behind is then removed from the remaining parts of the layer. This process is repeated until all the layers on the wafer have been applied.

One of the most prominent objects in the development of the projection exposure apparatuses is to be able to define lithographically structures having increasingly smaller dimensions on the wafer. Small structures result in high integration densities. This generally has a favorable effect on the performance of the microstructured components produced with the aid of apparatuses of such a type.

The size of the definable structures depends, above all, on the resolving power of the projection lens that is being used. Since the resolving power of the projection lenses is proportional to the wavelength of the projection light, one approach for the purpose of decreasing the resolving power consists in employing projection light having shorter and shorter wavelengths. The shortest wavelengths that are used at present are within the deep ultraviolet spectral region (DUV) and amount to 193 nm or occasionally even 157 nm.

Another approach for the purpose of decreasing the resolving power starts from the idea of introducing an immersion liquid having a high refractive index into an immersion interspace that remains between a final lens of the projection lens on the image side and the photoresist or another light-sensitive layer to be exposed. Projection lenses that are designed for immersion mode, and that are therefore also designated as immersion lenses, may attain numerical apertures (NA) of more than 1, for example 1.3 or 1.4. However, the immersion not only enables high numerical apertures, and thereby an increased resolving power, but also has a favourable effect on the depth of focus. The greater the depth of focus, the less demanding are the requirements as regards an exact positioning of the wafer in the image plane of the projection lens. In the broader sense, one also speaks of immersion when the light-sensitive layer is covered by an immersion liquid without the final optical element of the projection lens on the image side necessarily being immersed in the immersion liquid.

The implementation of immersion mode, however, requires considerable additional efforts in terms of structure and process engineering. For instance, it has to be ensured that the optical properties of the immersion liquid are spatially homogeneous and temporally constant—at least within the volume exposed to the projection light—even when the wafer with the photoresist applied thereon is moving relative to the projection lens. At the present time the associated technological problems have not been solved satisfactorily.

SUMMARY OF THE INVENTION

It is an object of the invention to specify a projection exposure apparatus designed for immersion mode that, with a simple structure, enables reliable and low-maintenance operation.

This object is achieved by means of a projection exposure apparatus with an illumination system for generating projection light. The apparatus further comprises a projection lens with which a reticle can be imaged onto a light-sensitive layer. The projection lens is designed for immersion mode, in which a final lens of the projection lens on the image side is immersed in an immersion liquid. According to the invention, a terminating element is provided that is transparent in respect of the projection light and is capable of being arranged between the final lens on the image side and the light-sensitive layer in such a way that it is immersed in the immersion liquid, at least with its image-side boundary surface.

The provision of a terminating element in the interspace between the final lens of the projection lens on the image side and the light-sensitive layer has, inter alia, the advantage that constituents issuing from the light-sensitive layer, or other contaminants arising there, are able to accumulate on the final lens on the image side at worst to a negligible extent, since the terminating element, in particular the side thereof facing towards the light-sensitive layer, acts like a protective shield for the final lens on the image side. In this way the final image-side lens of the projection lens does not have to be removed, but only the terminating element occasionally has to be removed and mounted again after cleaning or exchange. Particularly if the terminating element is fastened to the projection lens from outside and can be removed and mounted without disassembly of the projection lens, the effort required for this remains comparatively low.

It is advantageous if an interspace that is capable of being filled up at least partially with immersion liquid remains between the final lens of the projection lens on the image side and the terminating element. In this further embodiment the terminating element is consequently immersed in immersion liquid on both sides, so that a slight refraction of light occurs also on the boundary surface of the terminating element on the object side. The requirements as regards the adjustment and the manufacturing accuracy of the terminating element are correspondingly low. For, especially in the case of large numerical apertures, even a terminating element with plane-parallel shape reacts very sensitively to manufacturing defects, for example deviations from the nominal thickness, from the parallelism of the boundary surfaces and fitting errors.

If the interspace is not filled completely with immersion liquid but only partially, a gas-filled region remains between the immersion liquid and the final lens on the image side. This may be advantageous, for example, when the projection lens is to be capable of being converted between dry operation and immersion mode with as little effort as possible. The fewer interspaces between fixed optical elements such as lenses or terminating elements are filled with immersion liquid, the less effect a change-over to immersion mode generally has on the adjustment of the projection lens. From this point of view it may even be advantageous not to allow the projection lens to be immersed in the immersion liquid, but to leave a gas-filled region between the terminating element and the immersion liquid.

In an advantageous further embodiment of this configuration the projection lens exhibits, for the purpose of introducing immersion liquid into the interspace between the final lens on the image side and the terminating element, a first immersion device which is independent of a second immersion device for introducing immersion liquid into the interspace between the final optical element and the light-sensitive layer, so that no exchange of immersion liquid between the interspaces is possible. In this way it is ensured that contaminants issuing from the light-sensitive layer are unable to reach the final lens of the projection lens on the image side via the immersion liquid.

In another advantageous configuration the terminating element has the same refractive index as the final lens of the projection lens on the image side and is optically coupled onto this lens with its object-side boundary surface in such a way that projection light passing through the projection lens is not refracted between the final lens on the image side and the terminating element. The absence of any refraction between the final lens and the terminating element results in a still smaller adjustment effort in the course of exchanging the terminating element. This can be realized, for example, by the final lens on the image side, the terminating element and also the immersion liquid located in between them having the same refractive index.

A refraction of the projection light between the final lens on the image side and the terminating element is also forestalled when the terminating element is optically contacted with the final lens on the image side and both elements have the same refractive index. But optical contacting is also useful, in appropriate circumstances, in the case of differing refractive indices, since in this way the final lens on the image side is directly protected against contaminants by the terminating element which is optically contacted therewith. The terminating element can be optically contacted with the final lens on the image side in particularly simple manner if the two boundary surfaces facing towards one another are flat. An adjustment is then superfluous, since the position of the terminating element along the optical axis and also the orientation in the plane perpendicular thereto are predetermined by the flat boundary surfaces.

In an advantageous configuration a first interspace that is capable of being filled up with a first immersion liquid remains between the final lens of the projection lens on the image side and the terminating element. A second interspace that is capable of being filled with a second immersion liquid remains between the terminating element and the light-sensitive layer. The first interspace in this configuration is consequently capable of being separated from the second interspace in fluidically sealing manner.

The first immersion liquid and the second immersion liquid do not necessarily have to be different. But the use of differing immersion liquids has the advantage, inter alia, that the immersion liquids can be optimally adapted to the specific conditions in the two interspaces. The first immersion liquid, which is in contact with the final lens of the projection lens on the image side, may for example have a very low surface tension, which for the second immersion liquid coming into contact with the light-sensitive layer would no longer be acceptable. The first immersion liquid also does not definitely have to be so easily cleanable as the second immersion liquid, since it cannot be contaminated by the light-sensitive layer. An adaptation of the two immersion liquids from the point of view of chemical reactivity can furthermore be undertaken. Since, for example, quartz glass and calcium-fluoride crystals interact differently with adjoining liquids, the immersion liquids may be selected in such a way that they react chemically as little as possible with the adjoining optical faces.

The terminating element in this configuration may be arranged in displaceable manner. This makes it possible to distribute the shear forces acting on the immersion liquid, which arise as a result of the relative movement between the fixed projection lens and the light-sensitive layer, between the first immersion liquid and the second immersion liquid in a practically arbitrary ratio.

If during a scanning operation of the projection exposure apparatus the terminating element is displaced synchronously with the light-sensitive layer, constant distributions of force in the immersion liquids can be achieved over the entire scanning operation. This favors the formation of laminar flows of liquid, counteracting the formation of bubbles. This applies, in particular, if the terminating element is displaced in a plane parallel to the light-sensitive layer.

With regard to minimal movements of the second immersion liquid, the terminating element and the light-sensitive layer may have like displacement speeds and displacement directions during a projection. There is then no longer any relative movement between the terminating element and the light-sensitive layer. The second immersion liquid then remains with freedom of movement within the second interspace, despite the common displacement movement of the light-sensitive layer and of the terminating element. For this reason it may also have a higher viscosity than the first immersion liquid.

If flows within the second immersion liquid still arise, these have their origin in inertial forces which appear in the course of acceleration and deceleration during a scanning operation. If these inertial forces are small enough, additional measures, which are otherwise necessary in order to keep the immersion liquid in the interspace between the final lens on the image side and the light-sensitive layer, can be dispensed with. Since these measures generally promote bubbling, this configuration of the invention permits bubbles in the region of the second immersion liquid to be very largely avoided.

Although in the region of the first immersion liquid a relative movement occurs between the projection lens and the terminating element in the course of a scanning operation, and as a result shear forces also arise that act on the first immersion liquid, the terminating element may, unlike the wafer, be provided with an edge which prevents an undesirable discharging of the first immersion liquid during scanning operation. Therefore also for the first immersion liquid no additional measures, such as, for instance, an incident flow of gases, are necessary in order to prevent a discharging of the immersion liquid. Consequently bubbles cannot arise, or cannot arise to an appreciable extent, in the first immersion liquid either.

The edge may be formed directly on the terminating element. The edge may also be part of a tank which is open in the direction towards the final lens of the projection lens on the image side and in the bottom of which the terminating element is arranged. The tank itself may then consist of an opaque material, for example a metal or a crystal. Crystals such as crystalline silicon, for example, have the advantage of being very dimensionally stable. On account of their low specific weight, their stiffness and their low chemical reactivity, ceramics, for example based on SiC, are also highly suitable as material for the tank. The terminating element, which, for example, may consist of quartz glass, then forms merely a type of window at the bottom of the tank, through which the projection light can pass.

In addition to having translational displaceability, the terminating element may also be capable of being tilted about a tilt axis parallel to the image plane. The tiltability constitutes an additional degree of freedom, with which movements of the first and second immersion liquids can be influenced.

If the terminating element is, for example, tilted during a positioning movement in an exposure intermission in such a way that the largest spacing between the terminating element and the light-sensitive layer is situated at the front in the direction of motion, a kind of wedge-shaped gap arises between the terminating element and the light-sensitive layer. In this gap the second immersion liquid is entrained in the course of a positioning movement of the wafer over and beyond the light-sensitive layer. The tilting movement in this case may be effected in such a way that the shortest spacing between the terminating element and the light-sensitive layer is so small that, as a consequence of cohesive forces, the second immersion liquid is unable to pass through this gap. By virtue of this it is possible to displace the second immersion liquid over the surface of the wafer in very simple manner, also over greater distances and at greater speeds.

If an edge is provided on the terminating element, said edge should be dimensioned in such a way that in the course of a tilting movement of the terminating element the second immersion liquid is nevertheless prevented by the edge from discharging. Hence also in the course of positioning movements of the wafer, which are generally carried out at greater speeds than the displacement movements during an exposure, the necessity of entraining an immersion liquid with the aid of incident flows of gases, or with similar measures, also ceases to apply. Consequently no appreciable formation of bubbles can occur, even in the course of positioning movements.

Alternatively, or also in addition to tiltability of the terminating element, there may be provision to displace the terminating element perpendicular to the image plane. The spacing between the light-sensitive layer and the terminating element may then, for example, be reduced so far that the immersion liquid remains in the second interspace solely by virtue of cohesive forces.

If the second immersion liquid cannot be kept in the vicinity of the final lens on the image side merely by virtue of the cohesive forces or by virtue of a tilting of the terminating element in the course of a movement of the wafer relative to the projection lens, a holding device known as such may additionally be provided, which holds the second immersion liquid in the second interspace in non-contacting manner. For this purpose the holding device may comprise, for example, at least one gas nozzle, the discharge aperture of which can be directed towards the second immersion liquid.

In another advantageous configuration of the invention, at least the first interspace is arranged in a sealable container. The container may be, for example, a type of housing which is penetrated by the projection lens and which covers the entire supporting structure for the wafer. As a result of evaporation of the immersion liquid, after some time a saturation vapor pressure arises within the container, which prevents more immersion liquid from evaporating than condenses again simultaneously. In this way, latent heat of evaporation may not arise at those places where the immersion liquid comes into contact with a surrounding gas. Heat-sinks of such a type bring about an inhomogeneous distribution of temperature and hence also an inhomogeneous distribution of refractive index of the immersion liquid, as a result of which the imaging properties are impaired.

In general, however, it takes a very long time until the saturation vapor pressure has arisen in the container merely as a result of evaporation on the relatively small surface. Therefore the projection exposure apparatus may comprise a supply device for supplying a vapor phase of the first immersion liquid in the container. Even if the first immersion liquid differs from the second immersion liquid, in general it is not necessary also to counteract an evaporation of the second immersion liquid, since as a consequence of the terminating element the interface to a surrounding gas is very small.

A minimal cooling of the first immersion liquid is obtained when the vapor pressure of the vapor phase of the first immersion liquid in the container is capable of being adjusted in such a way that it is at least approximately equal to the saturation vapor pressure of the vapor phase of the first immersion liquid at the temperature prevailing in the container.

Another possibility for forestalling fluctuations of temperature within the first immersion liquid as a consequence of local evaporation consists in covering the first interspace in the upward direction at least partially by means of a cover. The cover reduces the size of the interface to a surrounding gas, on which cooling can occur as a result of evaporation. This cover may, for example, be constructed in such a way that only a small interspace filled with a gas remains between the cover and the first immersion liquid. The saturation vapor pressure arises relatively quickly there as a result of evaporation.

But the gas in the interspace may also be a special protective gas, the density of which is greater than the density of a surrounding gas. As a consequence of the greater density, the protective gas is kept in the interspace by the force of gravity. The protective gas should furthermore be such that the solubility thereof in the second immersion liquid is as low as possible, preferably lower than 10⁻⁴ per cent by volume. In this way an undesirable diminution of the transmitting power, or changes in refractive index within the second immersion liquid that have their origin in protective gas that has. gone into solution, can be counteracted.

It is more favorable if the first immersion liquid directly adjoins the cover, so that an interface to a surrounding gas or to the aforementioned protective gas remains only where the cover is interrupted.

This may be the case, for example, in the region of a recess which is provided in the region of the final lens on the image side. The cover does not then touch the projection lens; at the same time, an equalisation of level may take place via the peripheral gap between the lens and the cover, so that the volume between the terminating element and the cover is always completely filled with the first immersion liquid.

In this connection it is particularly favourable if the tank has an edge that slides in sealing manner along the underside of the cover during the displacement movement of the terminating element. The edge prevents, on the one hand, a lateral discharging of the first immersion liquid. At the same time, with its upward-pointing lateral face it forms a seal acting in the direction towards the cover.

A liquid film consisting of the first immersion liquid and acting as a lubricating seal may always remain between an upward-pointing lateral face of the edge and the cover. In order that this liquid film does not break away during a movement of the tank, a liquid reservoir may be sunk in the upward-pointing lateral face of the edge, out of which immersion liquid can subsequently flow. The immersion liquid may be under pressure in the liquid reservoir, so that the liquid film does not break away even when the relative movement between the tank and the cover generates an underpressure in the marginal region of the edge. The pressure in the liquid reservoir may, for example, be generated by first immersion liquid being capable of being supplied under pressure to the liquid reservoir from outside the tank.

In order to collect small amounts of the first immersion liquid which pass through the narrow gap between the edge of the tank and the cover and which display a lubricating action, on at least one outer side of the edge an overflow channel may be arranged which collects the overflowing first immersion liquid and conducts it away.

In addition, in all the aforementioned configurations the terminating element may have has at least approximately the same refractive index as the first and second immersion liquids. In this way it is ensured that small maladjustments of the terminating element barely have any effect on the optical properties of said liquids. For this reason the refractive index of the terminating element may differ from the refractive index of the adjoining immersion liquids by no more than 1% and preferably by no more than 0.5%.

This can be obtained, for example, by the adjoining immersion liquids being water and by the terminating element consisting of LiF.

It is particularly favorable if the terminating element is without refractive power. “Without refractive power” here is to be understood to mean the property of an optical element of having no focusing or defocusing effect. An example of such an optical element is a plane-parallel plate made of a homogeneous material. Such a plate does in fact have an effect on the position of the image plane of the projection lens and on the correction of the spherical aberration and must to this extent be taken into account in the design of said projection lens. However, provided that a difference in refractive index exists at the boundary surfaces, such a plate offsets beams impinging at an angle merely in parallel, the magnitude of the offset depending on the angle of incidence. A terminating element without refractive power is advantageous for the reason that, in this way, the requirements regarding the adjustment thereof can be lowered further and consequently the adjustment effort after a cleaning or an exchange of the terminating element is again reduced.

Quartz glass, for example, enters into consideration by way of material for the terminating element. Since in the case of very short-wave projection light in the deep ultraviolet spectral region, in particular at a wavelength of 157 nm, quartz glass and other conventional optical materials are no longer sufficiently transparent, the use of calcium-fluoride, barium-fluoride or strontium-fluoride crystals or even of mixed crystals such as calcium barium fluoride, for instance, has been proposed as a substitute. These materials also enter into consideration for the terminating element. However, these cubic crystals exhibit an intrinsic birefringence which results in an impairment of the imaging properties of the projection lens unless appropriate countermeasures are taken.

For this reason the terminating element may comprise at least two members consisting of one of the stated crystals, the thicknesses of which are so chosen, and the crystal lattices of which are so orientated relative to one another, that the influence of intrinsic birefringence on projection light passing through is at least approximately compensated.

The members may, for example, be joined to one another seamlessly or may even be spaced from one another in the direction of the optical axis. In the last-mentioned case an interspace remaining between the members, which may be sealed all round, can likewise be filled with a liquid that is transparent for the projection light. The faces adjoining the interspace between the members do not definitely have to be flat but may also exhibit a curvature. If the face of the object-side partial element pointing towards the interspace is concave and/or if the face of the image-side members pointing towards the interspace is convex, then a good compensation of the intrinsic birefringence can be achieved also for beams that pass through the terminating element inclined at large aperture angles.

In another advantageous configuration of the invention, at least one face of the terminating element passed through by projection light is reworked by local removal of material with a view to correcting wavefront errors. This process, which is known as such, of compensating for wavefront deformations by slight removal of material, of the order of magnitude of a few nanometres, can be employed particularly effectively in the case of the terminating element, since the latter is located in the immediate vicinity of the image plane. In this connection it is to be noted that the quotient of the refractive indices of the terminating element and of the immersion liquid is less than in dry systems without immersion liquid, so that correspondingly more material has to be removed in order to achieve the same effect as in dry systems. Particularly when the terminating element is a plane-parallel plate, the reworking of one or both faces turns out to be particularly easy.

In another advantageous configuration of the invention a protective layer that is impermeable in respect of immersion liquid is applied onto at least one surface of the terminating element that is able to come into contact with immersion liquid. Such a protective layer is advantageous in particular when fluoride crystals are used as material for the terminating element, since these crystals exhibit a relatively high solubility in water. As a result of the application of a layer of such a type, the material can be prevented from being corroded if water or a substance containing water is used by way of immersion liquid. The application of such a protective layer is advantageous not only in conjunction with a terminating element but quite generally in the case of all optical elements consisting of cubic fluoride crystals, particularly in the case of calcium-fluoride crystals that may come into contact with the immersion liquid.

In the course of the application of a protective layer, care should be taken to ensure that the latter completely covers the face to be protected. Even extremely small openings in the protective layer may result in a penetration of immersion liquid and in the formation of underlayer corrosion. From this point of view, an ion-assisted deposition of a protective layer of extremely high compactness (preferably greater than 98%) is advantageous, since as a result a local detachment of the protective layer in the course of operation of the projection exposure apparatus is largely prevented. The “compactness” of a material here is to be understood to mean, for a given degree of crystallinity, the ratio of the specific density of the material to a reference density at which the material is perfectly free from cavities.

BRIEF DESCRIPTION OF THE DRAWINGS

Further advantages and features of the invention will become apparent from the following description of the exemplary embodiments on the basis of the drawing. Shown therein are:

FIG. 1 a meridional section through a projection exposure apparatus according to a first exemplary embodiment of the invention in greatly simplified, not-to-scale, schematic representation;

FIG. 2 an enlarged detail from the image-side end of a projection lens which is an integral part of the projection exposure apparatus shown in FIG. 1;

FIG. 3 a projection exposure apparatus according to a second exemplary embodiment of the invention in a representation corresponding to FIG. 2, wherein the terminating element is optically contacted with the final lens on the image side;

FIG. 4 a projection exposure apparatus with an additional horizontal partition according to a third exemplary embodiment of the invention in a detail representation corresponding to FIG. 1;

FIG. 5 a projection exposure apparatus with a displaced terminating element according to a fourth exemplary embodiment of the invention in a detail representation corresponding to FIG. 1;

FIG. 6 an enlarged detail from the image-side end of the projection lens which is an integral part of the projection exposure apparatus shown in FIG. 5, in a first displaced position of the support and of the terminating element;

FIG. 7 the image-side end of the projection lens from FIG. 6 in a second displaced position of the support and of the terminating element;

FIG. 8 the image-side end of the projection lens from FIG. 6 with tilted terminating element;

FIG. 9 an enlarged detail from the image-side end of a projection lens according to a fifth exemplary embodiment of the invention, wherein an additional cover covers the first interspace;

FIG. 10 a further enlarged detail D from FIG. 9, in which the transition between the cover and an edge of a tank receiving the first immersion liquid is shown;

FIG. 11 the image-side end of a projection lens according to a sixth exemplary embodiment of the invention, wherein the image-side face of the final optical element on the image side is curved;

FIG. 12 the image-side end of a projection lens according to a seventh exemplary embodiment of the invention, wherein a gas-filled interspace remains between the final optical element on the image side and the immersion liquid;

FIG. 13 the image-side end of a projection lens according to an eighth exemplary embodiment of the invention, wherein the terminating element is divided up into two members along a curved face;

FIG. 14 the image-side end of a projection lens according to a ninth exemplary embodiment of the invention with terminating element divided up in curved manner, which is completely received in immersion liquid;

FIG. 15 the image-side end of a projection lens according to a tenth exemplary embodiment of the invention, wherein a gas-filled interspace remains between the terminating element and the immersion liquid;

FIG. 16 the image-side end of a projection lens according to an eleventh exemplary embodiment of the invention, wherein only the interspace between the final optical element on the image side and the terminating element is filled with immersion liquid.

DESCRIPTION OF PREFERRED EMBODIMENTS

FIG. 1 shows, in greatly simplified schematic representation, a meridional section through a microlithographic projection exposure apparatus denoted overall by 10 according to a first exemplary embodiment of the invention. The projection exposure apparatus 10 exhibits an illumination system 12 for generating projection light 13, which, inter alia, comprises a light source 14, illuminating optics indicated by 16, and a diaphragm 18. In the exemplary embodiment that is represented, the projection light has a wavelength of 157 nm.

The projection exposure apparatus 10 further includes a projection lens 20 which contains a plurality of lenses, only a few of which, for the sake of clarity, are represented in exemplary manner in FIG. 1 and denoted by L1 to L5. By reason of the short wavelength of the projection light 13, the lenses L1 to L5 are fabricated from calcium-fluoride crystals, which are still sufficiently transparent even at these wavelengths. The projection lens 20 serves to image, in reduced manner, a reticle 24 which is arranged in an object plane 22 of the projection lens 20 onto a light-sensitive layer 26 which is arranged in an image plane 28 of the projection lens 20 and applied on a support 30.

The support 30 is fastened to the bottom of a tank-like container 32 which is open in the upward direction and which is capable of being displaced, in a manner not represented in any detail, parallel to the image plane 28 with the aid of a displacing device. The container 32 is filled up so far with an immersion liquid 34 that during operation of the projection exposure apparatus 10 the projection lens 20 is immersed in the immersion liquid 34 with its final lens L5 on the image side. In the exemplary embodiment that is represented, this lens L5 is a large-aperture and comparatively thick lens; but here a plane-parallel plate is also to be encompassed by the term “lens”.

Via a supply line 36 and a drainage line 38 the container 32 is connected to a conditioning unit 40 in which a circulating pump, a filter for cleaning immersion liquid 34, and also a temperature-control device are contained in a manner known as such and therefore not represented in any detail. The conditioning unit 40, the supply line 36, the drainage line 38 and also the container 32 form overall an immersion device denoted by 42 in which the immersion liquid 34 is circulated and in the process cleaned and kept at constant temperature. The immersion device 42 serves, in a manner known as such, for increasing the resolving power and/or the depth of focus of the projection lens 20.

In an interspace 43 remaining between the final lens L5 on the image side and the light-sensitive layer 26 an exchange element 44 is arranged, the details of which will be elucidated in the following on the basis of FIG. 2.

FIG. 2 shows the image-side end face 45 of the projection lens 20 in an enlarged detail from FIG. 1. In the enlarged representation it can be discerned that the terminating element 44 has the shape of a plane-parallel plate with, for example, a circular or rectangular base area and is separably and adjustably attached to the image-side end face 45 of the projection lens 20 via two fastening elements indicated by 46 and 48. With a view to illustrating the separability, a screw connection 52 is indicated at the fastening element 46. For the purpose of adjustment, fine-adjustment drives are provided which are indicated in FIG. 2 by micrometer screws 54, 55, 56 and 57.

The terminating element 44 comprises two plate-like members 44 a and 44 b connected to one another, which have the same dimensions and which bear against one another seamlessly. By reason of the short wavelength of the projection light 13, the two members 44 a and 44 b are also each fabricated from calcium-fluoride crystals. The crystal lattices of the two members 44 a, 44 b are orientated in such a way that a rotationally symmetrical distribution of intrinsic birefringence results overall for the terminating element 44. As an alternative to this, the terminating element 44 may also comprise more than two members with differing crystal orientations. With a total of four plane-parallel members it is, for example, possible to compensate for the delay caused by intrinsic birefringence to a very large extent for arbitrary directions of incidence. Examples of the crystal orientations considered here can be gathered, for example, from WO 02/093209 A2, from WO 02/099450 A2 and also from US 2003/0011896 A1. The full disclosure of these applications is incorporated herein by reference.

In the case of the first exemplary embodiment shown in FIG. 2 the immersion liquid 34 flows around the exchange element 44 from all sides and is located, in particular, in the two gap-like interspaces 64 and 66 which remain between the terminating element 44, on the one hand, and the light-sensitive layer 26 or the final lens L5 on the image side, on the other hand.

If emission of substances from the light-sensitive layer 26, or a mechanical detachment of relatively small parts thereof, occurs during the operation of the projection exposure apparatus 10, then the terminating element 44 prevents contaminants contained in the immersion liquid 34 from being able to reach the flat image-side boundary surface 68 of the final lens L5 of the projection lens 20 in unhindered manner. Although such a contact is also not totally ruled out, since the two gap-like interspaces 64 and 66 are not completely separated from one another, an exchange of liquid between the gap-like interspaces 64 and 66 is at least made considerably more difficult by the terminating element 44 situated in between. For this reason, contaminated immersion liquid 34 practically does not ascend to the final lens L5 but is predominantly supplied via the drainage line 38 to the conditioning unit 40 and cleaned therein.

By reason of the protective effect of the terminating element 44 it is hardly still necessary to exchange the final lens L5 on account of contamination by contaminated immersion liquid 34 and, in connection therewith, to adjust it in elaborate manner.

An exchange of the terminating element 44, on the other hand, which is exposed in far higher measure to the contaminants emanating from the light-sensitive layer 26, turns out to be comparatively easy. For, in order to do this, the fastening elements 46 and 48 merely have to be loosened from the housing of the projection lens 20 with the aid of the screw connections 52. The installation of the terminating element 44, which immediately follows a cleaning or an exchange, also requires little adjustment and is therefore easy. By reason of the design in the form of a plane-parallel plate, the terminating element 44 is without refractive power and therefore has only comparatively little effect on the imaging properties. This holds, in particular, also for the reason that the terminating element 44 floats in the immersion liquid 34, so that, given suitable choice of the immersion liquid, only a very slight or even infinitesimal refractive effect arises at the boundary surfaces exposed to the projection light 13.

For all the optical elements that are fabricated from fluoride crystals and that are able to come into contact with immersion liquid a protective layer is applied, preferably at least on the optically active faces, which protects the sensitive crystals from the immersion liquid. In the first exemplary embodiment represented in FIG. 2, protective layers 74, 76 and 78 of such a type are therefore applied onto the flat image-side boundary surface 68 of the lens L5 and also onto the upper side 70 and onto the underside 72 of the terminating element 44.

The choice of the materials for the protective layers 74, 76 and 78 depends, above all, on the immersion liquid that is employed, which in turn is chosen taking the wavelength of the projection light that is being used into account. In the case of light wavelengths of 193 nm, water, for example, enters into consideration by way of immersion liquid, which rapidly corrodes crystalline calcium fluoride on account of the relatively high solubility thereof in water. In this case the protective layers 74, 76, 78 may consist of SiO₂ or LaF₃, since these materials are not soluble in water.

In the case of a light wavelength of 157 nm, as used in the exemplary embodiment described above, certain oils have a higher transparency than water and are therefore better suited by way of immersion liquid. The likewise highly transparent materials MgF₂ and LaF₃, for example, then enter into consideration as materials for the protective layers 74, 76, 78.

The protective layers 74, 76, 78 consisting of the stated materials can be applied onto the boundary surfaces of the optical elements in question by evaporation coating in a vacuum.

FIG. 3 shows, in a representation based upon FIG. 2, a second exemplary embodiment of a microlithographic projection exposure apparatus, wherein for like parts use is made of the same reference numerals as in FIG. 2 and for parts corresponding to one another use is made of reference numerals augmented by 200. In the second exemplary embodiment the terminating element 244 is not separated from the final lens L205 on the image side via an interspace 66 but is optically contacted with said lens directly. Provided that the lens L205 and the terminating element 244 are fabricated from a material having the same refractive index, the projection light 13 passes through the boundary surface between the terminating element 244 and the final lens L205 without being refracted. The fastening by optical contacting has the advantage that no fastening elements 46, 48 are required. In addition, after an exchange the terminating element 244 practically does not need to be adjusted, since the two flat boundary surfaces 270 and 268 facing towards one another pertaining to the terminating element 244 and to the lens L205, respectively, guarantee the correct arrangement by themselves in the course of optical contacting.

The image-side face 272 of the terminating element 244 is reworked at some points 79 a, 79 b—represented in FIG. 3 on a greatly exaggerated scale—by removal of material amounting to a few nanometres in such a way that wavefront errors caused by the projection lens 220 are corrected. Since reworking methods of such a type are known as such, a more detailed elucidation will be dispensed with.

FIG. 4 shows, in a representation based upon FIG. 1, a third exemplary embodiment of a projection exposure apparatus, wherein for like parts use is made of the same reference numerals as in FIG. 1 and for parts corresponding to one another use is made of reference numerals augmented by 300. The projection exposure apparatus shown in FIG. 4 differs from that shown in FIG. 1 in that it comprises not just one but two immersion devices 342 a and 342 b which are independent of one another. The container 332 here is subdivided horizontally by a partition 80 into two partial containers 332 a and 332 b in such a way that the gap-like interspace 366 between the terminating element 44 and the final lens L5 on the image side is arranged totally within the partial container 332 a, and the gap-like interspace 364 between the terminating element 44 and the light-sensitive layer 26 is arranged totally within the partial container 332 b. The terminating element 44 is sunk with clearance in a suitably shaped cut-out 82 in the partition 80 between the partial containers 332 a and 332 b.

By virtue of the separation of the immersion liquids 334 a and 334 b in separate immersion devices 342 a and 342 b, contaminated immersion liquid from the partial container 332 b is prevented from getting into the gap-like interspace 366 between the terminating element 44 and the lens L5 and from being able to contaminate the latter in this way.

In the following a fourth exemplary embodiment will be described on the basis of FIGS. 5 and 6, which show schematically a detail from the image-side end of a projection lens, and an enlarged detailed representation thereof, respectively. Parts similar to those in FIGS. 1 to 4 are denoted by like reference numerals, and parts corresponding to one another are denoted by reference numerals augmented by 400.

In the fourth exemplary embodiment a terminating element 444 is provided parallel to the image plane 28. The terminating element 444 is likewise constructed in the form of a plane-parallel plate which, however, is considerably larger than in the exemplary embodiments described above. In the exemplary embodiment that is represented, the terminating element 444 has a rectangular basic shape and is sunk into a bottom 486 of a tank 488. The tank 488, which, for example, may be fabricated from metal, a ceramic or a crystal, serves for receiving a first immersion liquid 434 a, which in the exemplary embodiment that is represented is de-ionised water. An edge 490 of the tank 488 is so high that, given an appropriate filling height of the first immersion liquid 434 a, a first interspace 492 remaining between the final lens L5 on the image side and the terminating element 444 is filled out completely with the first immersion liquid 434 a.

Between the terminating element 444 and the light-sensitive layer 26 there remains a flatter second interspace 494 which is filled with a second immersion liquid 434 b. In the exemplary embodiment that is represented, the second immersion liquid 434 b is likewise de-ionised water. The second interspace 494 is so flat that the second immersion liquid 434 b is hindered solely by cohesive forces from discharging laterally out of the second interspace 494. The smaller the spacing between the terminating element 444 and the light-sensitive layer 26, the better do the cohesive forces hold the second immersion liquid 434 b in the second interspace 494.

In order to reduce the requirements as regards the parallelism of the terminating element 444 relative to the image plane 28, a material having a refractive index that is as equal as possible to the refractive index of the surrounding immersion liquids 434 a, 434 b can be chosen for the terminating element 444. In the case where use is made of water by way of immersion liquid, LiF, which is still highly transparent at least at a wavelength of 193 nm, is suitable, for example, by way of material for the terminating element 444. The difference in the refractive indices then amounts to only 0.0066.

If the projection light has a particularly short wavelength, for example 157 nm, the first immersion liquid 434 a may also consist of a fluorinated hydrocarbon that has a higher transmission than water at these wavelengths. For the second immersion liquid 434 b the somewhat lower transmission is not too disadvantageous, inasmuch as the height of the second interspace 494 will generally be very low. In addition, water has the advantage that it corrodes the light-sensitive layer 26 less severely than is the case, for instance, with fluorinated hydrocarbons.

In the fourth exemplary embodiment the projection exposure apparatus is designed for scanning operation. This means that the reticle 24 is displaced in the object plane 22 during the projection. Synchronously with this, the support 30 with the light-sensitive layer 26 applied thereon is also displaced parallel to the image plane 28. The lateral magnification of the projection lens 420 determines the ratio of the displacement speeds and the displacement directions of the reticle 24 and of the support 30.

For this purpose, the support 30 is clamped, with the aid of clamping elements 31 a, 31 b which are discernible in FIG. 5, on a displaceable table 33 which is ordinarily designated as a wafer stage. The table 33 can be displaced with great accuracy parallel to the image plane 28 in a manner known as such with the aid of actuating drives. The actuating drives are represented in simplified manner in FIG. 5 and are denoted by 35 a and 35 b.

Manipulators 497 a, 497 b are fastened to the table 33, so that said manipulators jointly execute displacement movements of the table 33. The manipulators 497 a, 497 b are connected to the tank 488 via actuating arms 498 a, 498 b. The manipulators 497 a, 497 b are constructed in such a way that they are able to move the tank 488 parallel to the image plane 28 and relative to the table 33, to displace it perpendicular thereto, i.e. parallel to an axis OA, and also to tilt it relative to the image plane 28. In the exemplary embodiment that is represented, tilting movements in particular are possible about two horizontal axes which extend perpendicular to directions of motion of the table 33 and perpendicular to the optical axis OA.

Furthermore, in FIG. 5 optional gas-discharge nozzles 499 a, 499 b are discernible, with which a stream of gas can be directed onto a peripheral gap which is formed between the edge 490 of the tank 488 and the light-sensitive layer 26.

The projection exposure apparatus show in FIGS. 5 and 6 operates as follows:

During a scanning operation the table 33 is displaced together with the manipulators 497 a, 497 b in the direction of the arrow 496 b (see FIG. 6) with the aid of the actuating drives 35 a, 35 b. The manipulators 497 a, 497 b execute no actuating movements during this process, so that the tank 488 with the terminating element 444 sunk therein moves synchronously and at the same displacement speed and in the same displacement direction with the table 33 and consequently also with the light-sensitive layer 26. In FIG. 6 this is indicated by an arrow 496 a which has the same direction and length as the arrow 496 b. The tank 488 consequently moves away beneath the projection lens 420 during the scanning operation together with the light-sensitive layer 26.

FIG. 7 shows, in a detail corresponding to FIG. 6, the relative position of the tank 488 and of the light-sensitive layer 26, on the one hand, and of the projection lens 420, on the other hand, at the end of the scanning operation. Since the tank 488 moves synchronously, in parallel and at the same displacement speed as the light-sensitive layer 26 during the scanning operation, no shear forces act on the second immersion liquid 434 b in the second interspace 494. The second immersion liquid 434 b therefore remains in the second interspace 494 also during the displacement movements of the support 30. An incident flow on the second immersion liquid 434 b with gases emerging from the discharge nozzles 499 a, 499 b may therefore be reduced or may even become superfluous. Hence one of the significant causes of the formation of bubbles in the second immersion liquid 434 b ceases to apply, either entirely or partially.

Since the first immersion liquid 434 a remains in the tank 488 solely by reason of the force of gravity, here too no incident flow with gases is required in order to prevent an escape of the immersion liquid during the scanning operation. Bubbles are also unable to arise to an appreciable extent as a result of the intermixing which the fixed projection lens 420 brings about in the first immersion liquid 434 a passing by. Such an intermixing is entirely desirable, since in this way the formation of relatively large temperature gradients is counteracted.

Overall it is possible for considerably diminished numbers of rejects to be achieved in this way, since neither in the first immersion liquid 434 a nor in the second immersion liquid 434 b can bubbles arise to an appreciable extent as a consequence of the displacement movements during a scanning operation.

Between consecutive exposure cycles it is frequently necessary to reposition the support 30, with the light-sensitive layer 26 applied thereon, with respect to the projection lens 420. The displacement speeds in the course of these positioning movements are generally distinctly higher than in the course of the movements during exposure.

If the tank 488 is exactly the same size as the light-sensitive layer 26 applied on the support 30, during positioning movements of such a type the tank 488 can be displaced just as synchronously and at the same speed as has been described above in connection with the scanning operations. In general, however, for various reasons it will be expedient if the tank 488 has smaller dimensions parallel to the image plane 28 than the light-sensitive layer 26 applied on the support 30. For example, the smaller the tank 488, the smaller also is the interface of the first immersion liquid 434 a to a surrounding gas. Accordingly, less heat of evaporation is also withdrawn from the first immersion liquid 434 a. This in turn has a favorable effect on a homogeneous distribution of temperature, and hence of refractive index, within the first immersion liquid 434 a. From this point of view it would be ideal if the tank 488 is only slightly larger than the region on the light-sensitive layer 26 that is exposed overall during a scanning operation.

For larger positioning movements, however, a smaller tank 488 means that the tank 488 cannot jointly execute this movement, at least not fully. In this case a relative movement between the light-sensitive layer 26 and the terminating element 444 is unavoidable. This relative movement is generated by the manipulators 497 a, 497 b which are fastened to the table 33.

In order to prevent formation of bubbles in the second immersion liquid 434 b also during a faster positioning movement of the support 30, in the fourth exemplary embodiment represented in FIGS. 5 to 7 the entire tank 488 can be additionally tilted with the aid of the manipulators.

In FIG. 8 the image-side end of the projection lens 420 is shown in a representation based upon FIGS. 6 and 7, the tank 488 having been tilted by 2°. The tilt axis, which is denoted in FIG. 8 by TA, extends perpendicular both to the optical axis OA and to the direction of motion 496 b of the support 30. By virtue of the tilting movement of the tank 488 about the axis TA, the second interspace 494, which has a constant height during a scanning operation, is given the shape of a wedge-like prism. In the tilted position of the tank 488 the end of the tank 488 situated at the rear in the direction of motion 496 b is removed just so far from the light-sensitive layer 26 that damage thereto is avoided. The cohesive forces now acting more strongly prevent, even at higher positioning speeds, the second immersion liquid 434 b from emerging from the second interspace 494, whereas the support 30 moves away in the direction of the arrow 496 b beneath the fixed or at worst slowly moving tank 488.

If during the scanning operations the spacing between the light-sensitive layer 26 and the terminating element 444 is so small that a tilting movement about the tilt axis TA could involve damage to the layer 26, alternatively a tilt axis may be chosen that extends through the end of the tank 488 situated at the rear in the direction of motion 496 b. For the manipulators 497 a, 497 b this means that the manipulator 497 b raises the side of the tank 488 situated at the front in the direction of motion by the requisite distance.

In order in the third exemplary embodiment shown in FIGS. 5 to 8 to prevent undesirable losses of heat of the first immersion liquid 434 a and of the second immersion liquid 434 b, the projection exposure apparatus exhibits a container 90 which tightly seals the space surrounding the immersion liquids 434 a, 434 b outwardly. Via an inlet 92, water vapor which is generated by an evaporator 94 can be introduced into the space surrounded by the container 90. The water vapor is introduced until such time as the saturation vapor pressure applying at the existing temperature is attained, at least approximately, within the space surrounded by the container 90. In this way the immersion liquids, which here each consist of water, are prevented from gradually evaporating, which would result in a cooling of the liquid at the interfaces to the surrounding atmosphere. It will be understood that in the event of a change-over to other immersion liquids other liquids also have to be evaporated correspondingly in the evaporator 94.

A fifth exemplary embodiment will be described in the following on the basis of FIGS. 9 and 10, which show schematically a detail from the image-side end of a projection lens and an enlarged detailed representation D thereof, respectively. Parts similar to those in FIGS. 1 to 4 are denoted by identical reference numerals; parts that have counterparts in the fourth exemplary embodiment bear reference numerals augmented by 100.

In the fifth exemplary embodiment, in contrast with the third exemplary embodiment shown in FIGS. 5 to 8, an additional cover plate 500 is provided which almost totally covers the tank 588 in the upward direction. The cover plate 500, which does not have to be transparent, exhibits an opening 502, through which the image-side end of the projection lens 520 is immersed in the first immersion liquid 534 a. The edge 590 of the tank 588 slides along the underside of the cover plate 500 in the course of a displacement movement of the tank 588 indicated by an arrow 596 a.

The space between the cover plate 500 and the tank 588 is filled out completely with the first immersion liquid 534 a. For this purpose the opening 502 is so dimensioned that a peripheral gap 504 remains around the image-side end of the projection lens 520, in which a liquid level can be adjusted.

FIG. 10 shows an enlarged detail D from the region of the edge 590. In the detail D it can be discerned that the edge 590 of the tank 588 is provided on its upward-pointing lateral face with a peripheral wedge-shaped groove 506 and with a likewise peripheral rectangular groove of larger cross-section, which constitutes a reservoir 508 for the immersion liquid 534 a. The reservoir 508 and the wedge-shaped groove 506, which is connected to the reservoir 508 via a duct 510, are always filled with the first immersion liquid 534 a, so that a thin liquid film is formed on the upward-pointing lateral face of the edge 590. This liquid film acts as a lubrication and in this way enables low-friction and vibration-free sliding of the tank 588 along the underside of the cover plate 500.

In order to ensure that the liquid film does not break away in the course of a movement of the tank 588 away beneath the cover plate 500, with gas bubbles thereby being introduced into the first immersion liquid 534 a, the first immersion liquid 534 a in the reservoir 508 and in the wedge-shaped groove 506 is under a slight overpressure. This overpressure is generated by first immersion liquid 534 a being constantly supplied under pressure to the reservoir 508 via a supply line 512. At the same time, excess first immersion liquid 534 a is able to flow away via a drainage line 514. If the contact pressure generated by the dead weight of the cover plate 500 does not suffice by way of counterpressure, the cover plate 500 can be additionally loaded, for example with the aid of springs.

For the case where first immersion liquid 534 a emerges through a somewhat wider gap 516 on the outside of the edge 590, a peripheral overflow channel 518 is provided which collects emergent first immersion liquid 534 a and conducts it away in a manner not represented in any detail. A protective gas 519 that is heavier than air and that, for example, may have the property of having only very low solubility in respect of the first immersion liquid 534 a may be charged into the overflow channel 518. As a result, molecules from a gas surrounding the entire arrangement, which impair the optical properties of the first immersion liquid 534 a in undesirable manner, are prevented from going into solution. The protective gas 519 in the overflow channel 518 is may be renewed continuously, in order to counteract a gradual intermixing with the surrounding gas.

The seal in the region of the edge 590 is of importance to the extent that the support 30 of the light-sensitive layer 26 is not only frequently displaced in a plane parallel to the image plane 28 but, with a view to diminishing imaging errors, can also be tilted slightly about a horizontal axis. If the cover plate 500 is then not to be tilted together with it, the seal in the direction towards the edge 590 must be so constructed that it guarantees sufficient imperviousness in relation to the cover plate 500 even in the case of relatively small tilting movements of the tank 588.

If the case may arise that the lubrication by the first immersion liquid 534 a is not sufficient for a short time, for the cover plate 500 and the edge 590 it is advisable to choose materials or coatings of these parts that minimize or even entirely avoid a contamination of the first immersion liquid 534 a as a consequence of abrasion in the course of start-up. Aluminum oxide or diamond, for example, enter into consideration here as coatings.

The cover plate 500 has, on the one hand, the advantage that the occurrence of waves in the tank 588 is prevented. On the other hand, the cover plate 500 limits the interface of the first immersion liquid 534 a relative to a surrounding atmosphere to the narrow peripheral gap 504 which remains between the image-side end of the projection lens 520 and the cover plate 500. In this way only very little heat is withdrawn from the first immersion liquid 534 a as a consequence of evaporation. This in turn diminishes the temperature gradient and hence the refractive-index gradient within the first immersion liquid 534 a, which is formed in the course of heating by the projection light 13. In the case of the second immersion liquid 534 b the problem of evaporation does not exist to an appreciable extent, inasmuch as the interface between the second immersion liquid 534 b and a surrounding atmosphere is in any case very small.

In order to introduce the immersion liquids 534 a, 534 b into the first and second interspaces 592 and 594, respectively, a relatively small amount of the second immersion liquid 534 b may firstly applied onto the light-sensitive layer 26. Subsequently the underside of the tank 588 is mounted on one side or parallel, and the second immersion liquid 534 b is expressed in bubble-free manner. The spacing between the tank 588 and the light-sensitive layer 26 can later be adjusted precisely with the aid of the manipulators 497 a, 497 b.

Subsequently the cover plate 500 is laid over the tank 588. In order to fill the tank 588 with the first immersion liquid 534 a, the latter may, for example, be charged via the peripheral gap 504 which remains between the projection lens 520 and the cover plate 500. However, it will be easier if the edge 590 of the tank 588 is provided with an inlet and with an outlet, via which the first immersion liquid 534 a can be charged into the tank 588 and removed therefrom. During operation of the projection exposure apparatus the first immersion liquid 534 a may also be circulated continuously in a circuit, as elucidated in connection with the first three exemplary embodiments.

Of course, the arrangement shown in FIGS. 9 and 10 may likewise be accommodated in a container 90, as shown in FIG. 5 with reference to the fourth exemplary embodiment. In this way the evaporation of the immersion liquids is further reduced.

FIGS. 11 to 16 each show, in schematic representations based upon FIG. 2, the image-side end of projection lenses according to further exemplary embodiments of the invention. In these Figures, for parts similar to those in FIG. 2 use is made of the same reference numerals, and for parts corresponding to one another use is made of reference numerals that are augmented by 600, 700, 800, 900, 1000 and 1100, respectively.

In the sixth exemplary embodiment shown in FIG. 11 the image-side boundary surface 668 of the final lens L605 on the image side is not flat but curved in aspherically concave manner. For it has been shown that, in the case of immersion objectives in particular, an aspherically curved face in the immediate vicinity of the image plane 28 is particularly well suited for the correction of higher-order imaging errors. The prerequisite for this, however, is that the refractive indices of the final lens L605 on the image side and of the immersion liquid 34 differ sufficiently from one another.

In the case of the projection lens 620 the terminating element 644 also comprises two members 644 a, 644 b which are fabricated from calcium-fluoride crystals or from similar cubically crystalline crystals with suitably chosen crystal orientations. In the exemplary embodiment that is represented, the final lens L605 on the image side consists of quartz glass. As an alternative to this, the final lens L605 on the image side may likewise consist of a cubically crystalline material. The crystal orientations of the crystals that the final lens L605 on the image side and the members 644 a, 644 b consist of may then likewise be so aligned that a very extensive correction of the intrinsic birefringence is achieved. The way in which a reciprocal birefringence compensation can be achieved with three crystal orientations rotated relative to one another about the optical axis is described in detail in the printed publications WO 02/093209 A2, WO 02/099450 A2 and US 2003/0011896 A1 already mentioned above.

In the seventh exemplary embodiment represented in FIG. 12 the first interspace 792 remaining between the final lens L705 on the image side and the terminating element 744 is not filled with immersion liquid 34 completely but only partially. Therefore a gap-like interspace 793 filled with a surrounding gas remains between the final lens L705 on the image side and the immersion liquid 34.

This variant is particularly advantageous in the case of projection lenses that are provided both for dry operation and for immersion mode. In order to have to perform as few modifications as possible to the projection lens in the event of a change from dry operation to immersion mode, and vice versa, the optical conditions should change at as few boundary surfaces as possible. In the case of the projection lens 720, for this reason the image-side face 768 of the final lens L705 on the image side still adjoins a surrounding gas and not, for instance, immersion liquid 34.

On the other hand, also in the case of the projection lens 720 it is guaranteed that the terminating element 744 is surrounded by the immersion liquid 34 on both sides. On account of the lower refractive-index quotient at the boundary surfaces of the terminating element 744, positional tolerances and manufacturing tolerances of the terminating element 744 may consequently only have a slight effect on the imaging properties of the projection lens 720.

In the eighth exemplary embodiment shown in FIG. 13 the terminating element 844, which is plane-parallel overall, likewise comprises two members 844 a, 844 b which may consist of cubically crystalline materials with differing crystal orientations. In contrast with the exemplary embodiments described above, the boundary surface between the two members 844 a, 844 b in the case of the projection lens 820 is not flat but curved. Furthermore, the two members 844 a, 844 b are not optically contacted with one another directly but are spaced from one another, so that a narrow gap 899 remains between the members 844 a, 844 b, which in the case of the projection lens 820 is filled with a surrounding gas.

In the case of the projection lens 820 only the image-side partial element 844 b comes into contact with the immersion liquid 34. Therefore it will generally be sufficient to exchange only the partial element 844 b when required. The object-side partial element 844 a, on the other hand, may be mounted on or in the projection lens 820 in such a manner that an exchange can only be carried out with major effort. Consequently only the partial element 844 b constitutes an exchange element in the real sense of the word.

The partitioning of the terminating element 844 into two members 844 a, 844 b along a curved parting surface has the advantage that the image-side partial element 844 b is likewise relatively insensitive to manufacturing tolerances and positional tolerances. For, on the one hand, the image-side face is immersed in immersion liquid 34, so that the refractive-index quotient there is small. On the other hand, on the object-side face of the partial element 844 b only relatively small entrance angles arise by reason of the convex curvature thereof in the case of light beams that pass through the terminating element 844 at large angles relative to the optical axis, so that manufacturing tolerances and positional tolerances are able to have less effect there.

The projection lens 920 shown in FIG. 14 according to a ninth exemplary embodiment differs from the projection lens 820 merely by virtue of the fact that the immersion liquid 34 comes directly up against the final lens L905 on the image side. Therefore, unlike in the case of the projection lens 820 shown in FIG. 13, both the gap 999 remaining between the two members 944 a, 944 b and the first interspace 992 between the final lens L905 on the image side and the terminating element 944 are filled up with immersion liquid 34. Positional tolerances and manufacturing tolerances of the terminating element 944 have even less effect on the imaging properties of the projection lens in this variant.

Since, although the object-side partial element 944 a is exposed to the immersion liquid 34, it is relatively well protected by the final lens L905 on the image side or by the image-side partial element 944 b, also in the case of the projection lens 920 an exchange of optical elements on account of contamination may be restricted to the image-side partial element 944 b. However, the immersion liquid 34 reaching as far as the final lens L905 on the image side necessitates more extensive modifications if a change-over from dry operation to immersion mode is desired.

FIG. 15 shows an image-side end of a projection lens 1020 according to a tenth exemplary embodiment of the invention. Unlike in the case of the exemplary embodiments described previously, the terminating element 1044 is not immersed in the immersion liquid 34. The faces of the terminating element 1044 that are permeated by projection light consequently adjoin a surrounding gas both on the object side and on the image side. This arrangement is also advantageous, in particular, in the case of projection lenses that are to be suitable both for dry operation and for immersion mode. This is because the arrangement shown in FIG. 15 requires particularly few modifications in the event of a change-over between the operating modes. On the other hand, the optical conditions at the two boundary surfaces of the terminating element 1044 are largely identical. This is advantageous to the extent that, in particular, imaging errors that are generated by positional tolerances, for example tilting movements, at the object-side boundary surface, are compensated really well by imaging errors acting in the opposite sense on the image-side boundary surface.

The projection lens 1120 shown in FIG. 16 differs from the projection lens 1020 shown in FIG. 15 by virtue of the fact that the first interspace 1192 between the final lens L1105 on the image side and the terminating element 1144 is filled out not with a surrounding gas but with a liquid 1134. The image-side face of the terminating element 1114 is therefore comparatively insensitive to manufacturing tolerances, in particular fitting errors, of the terminating element 1144.

The second interspace 1194 between the terminating element 1144 and the light-sensitive layer 26 can be filled up either partially with immersion liquid 34, as is the case with the projection lens 1020 shown in FIG. 15. During dry operation, as shown by FIG. 16, the light-sensitive layer 26 is not covered by immersion liquid.

The above description of the preferred embodiments has been given by way of example. From the disclosure given, those skilled in the art will not only understand the present invention and its attendant advantages, but will also find apparent various changes and modifications to the structures and methods disclosed. The applicant seeks, therefore, to cover all such changes and modifications as fall within the spirit and scope of the invention, as defined by the appended claims, and equivalents thereof. 

1. An apparatus which, during operation, directs radiation along a path from an object plane to an image plane in a microlithography projection system, the apparatus comprising: a first optical assembly comprising a plurality of first optical elements arranged along the path; and a second optical assembly adjustably mounted with respect to the first optical assembly, the second optical assembly comprising one or more second optical elements positioned in the path including a final optical element, where the final optical element is the optical element closest to the image plane along the path, the final optical element having a surface facing the image plane, wherein the apparatus is a microlithography projection objective configured to include a liquid between the surface of the final optical element and the image plane, during operation, and to image an object positioned at the object plane onto a surface at the image plane using radiation having a wavelength of 193 nm or less, the apparatus having a numerical aperture at the image plane greater than
 1. 2. The apparatus of claim 1, wherein the second optical assembly is detachable from the first optical assembly without modification of the first optical assembly.
 3. The apparatus of claim 1, wherein the second optical assembly comprises a plurality of fastening elements that are fastened to the first optical assembly.
 4. The apparatus of claim 3, wherein the first optical assembly comprises a housing that contains the plurality of first optical elements and the fastening elements are fastened to the housing.
 5. The apparatus of claim 4, wherein the fastening elements comprise connectors accessible from outside the apparatus.
 6. The apparatus of claim 5, wherein the connectors are screws.
 7. The apparatus of claim 1, wherein the second optical assembly comprises actuators configured to adjust the second optical elements relative to the first optical elements.
 8. The apparatus of claim 7, wherein the actuators are micrometer screws.
 9. The apparatus of claim 1, wherein the first optical assembly comprises a housing that contains the plurality of first optical elements and the second optical elements are positioned outside of the housing.
 10. The apparatus of claim 1, wherein the liquid is water.
 11. The apparatus of claim 1, wherein the final optical element is the only second optical element in the second optical assembly.
 12. The apparatus of claim 1, wherein the second optical assembly comprises a second optical element positioned in the path between the final optical element and the first optical elements.
 13. The apparatus of claim 1, wherein the final optical element is a lens.
 14. The apparatus of claim 13, wherein the lens comprises a curved surface.
 15. The apparatus of claim 13, wherein the lens is a plano-convex lens.
 16. The apparatus of claim 1, wherein the apparatus is configured to include the liquid between a surface of a first optical element closest to the image plane and a surface of a second optical element furthest from the image plane, during operation.
 17. A microlithography projection system which, during operation, directs radiation along a path to a substrate at an image plane, the microlithography projection system comprising: an illumination system which, during operation, provides the radiation to an object positioned at an object plane, the radiation having a wavelength of 193 nm or less; a projection objective comprising a first optical assembly and a second optical assembly adjustably mounted with respect to the first optical assembly, the first optical assembly comprising a plurality of first optical elements arranged along the path between the object plane and the image plane, and the second optical assembly comprising one or more second optical elements positioned in the path between the first optical assembly and the image plane, the second optical assembly including a final optical element, where the final optical element is the optical element closest to the image plane along the path and the final optical element has a surface facing the image plane; a stage configured to position the substrate at the image plane; and a liquid supply apparatus which, during operation, provides a liquid between the surface of the final optical element and the substrate, wherein, during operation, the projection objective forms an image of the object at the image plane with the radiation, the projection objective having a numerical aperture at the image plane greater than
 1. 